Fluorescent lamp with shielded electrodes

ABSTRACT

A fluorescent electric lamp of the type having a tubular envelope with electrodes at the ends between which an electric discharge occurs is provided with radiation shields around the electrodes to prevent emission of electrode radiation from the lamp.

United States Patent 1191 Utt 1 Get. 23, 1973 [54] FLUORESCENT LAMP WITH SHIELDED 3,136,489 6/1964 Oharenko... 240 11.4 ELECTRODES 2,221,644 11/1940 Lucian.....'.. 313/109 X 2,030,806 2/1936 Wiegand. 313/204 Inventor: J N 0", sota, Fla. 1,037,290 9/1912 Moore 315/115 x 2,207,133 7/1940 Scott et a1 313/242 X [73] Assgnee" g g 3,426,234 2/1969 Hayasaka et 8.1.. 313/109 x arasma 2,965,778 12 1960 Jenkins BI a1. 313 109 x [221 17, 1972 FOREIGN PATENTS OR APPLICATlONS [21] App]. N0.: 235,774 1,128,560 4/1962 Germany 313/109 487,322 6/1938 Great Britain.... Related Applcat'on Data 852,728 11 1960 Great Britain 313/318 [63] Continuation of Ser. No. 56,370, July 20, 1970,

abandoned' Primary Examiner-Palmer C. Demeo Attorney-Richard E. Hosley [52] 111.5. Cl. 313/109, 313/220 [51] Int. Cl H0lj 61/35, l-lOlj 61/42 581 Field 01 Search 313/109, 206, 207, [57] ABSTRACT 313/242, 220; 315/85; 252/478 A fluorescent electric lamp of the type having a tubular envelope with electrodes at the ends between 5 References Cited which an electric discharge occurs is provided with ra- UNITED STATES PATENTS diation shields around the electrodes to prevent emis- 3 239 669 3,1966 w b 252/478 X sion of electrode radiation from the lamp.

em erger.... 3,536,920 10/1970 Sedlak et a1. 252/478 X 8 Claims, 4 Drawing Figures PATENTEDOBI 23 ms 3; 7' 67' 9 5 7 FIG. 4

INVENTOR JOHN NASH OTT $44M 5; MM

ATTORNEY FLUORESCENT LAMP WITH SHIELDED ELECTRODES This is a continuation of US. Pat. application Ser. No. 56370 filed July 20, 1970 now abandoned.

BACKGROUND OF THE INVENTION This invention relates to fluorescent electric discharge lamps of the type commonly used as a source of artificial illumination.

It is now recognized that natural electromagnetic ra diation from the sun and sky is an important environmental element affecting the health, growth and development of plants, animals and human beings. Also, it has been recognized that unnatural man-made radiation sources including, but not limited to artificial light sources, may constitute health and safety hazards if they emit radiation which has substantial energy distortions at various wavelengths as compared with natural radiation under which life on earth has evolved. The term light pollution has been used in describing the biological effects of light from artificial light sources whose radiations are characterized by such distortions. Since visible light lies in a relatively narrow wavelength band of 380 to 770 nanometers, a general term would be radiation pollution so as to encompass all wavelengths of the electromagnetic spectrum. Public concern with the problem of radiation pollution is evidenced by the enactment of Public Law No. 90-602 known as the Radiation Control for Health and Safety Act of 1968. This act is designed to study and control electronic product radiation and covers any ionizing or nonionizing electromagnetic or particulate r diili ni In the range of visible light, energy distortion of an artificial light source as compared with astandard such as natural sunlight, can be measured quite accurately by use of a spectrophotometer. With the aid of such measurements, light sources have been designed which emit visible light approximating natural daylight in spectral composition. Recently fluorescent lamps have become commercially available having light-emitting phosphors providing a spectral balance closer to natural light. 1 v. I

With respect to radiation pollution occurring outside the range of visible light, e.g., ultraviolet, infrared, X- rays, cosmic rays, etc. the problem of detecting radiation distortions and their biological effects is much more difficult. One reason for the difficulty is that measurement of such radiations by conventional measuring methods, particularly at low energy levels, is not precise. Another reason isthe difficulty in determining the long-term effects of low energy radiation distortion at various wavelengths.

Extensive studies by the inventor of plant growth under artificial light sources using time-lapse photography techniques have revealed that plants are very sensitive indicators of artificial radiation distortion. Lights used for photographic purposes having radiation deficiencies and distortions compared with natural light caused a variety of physiological responses in plants. For example, one type of photographic light resulted in the development of all male buds on a pumpkin vine whereas a different type of light resulted in the development of all female buds. It has been shown that radiation distortion affecting plants may also influence physiological growth responses in animals. Thus it has been demonstrated that the sex ratio of guppies and mice born of parents kept under different types of artificial light is affected. Still further, it is now known that light entering the eyes of human beings triggers the release of hormones affecting body chemistry and that the effect is dependent on the wavelength of light entering the eye.

One effect that has been noted is that unnatural radiation may affect the seed germination and growth rate of plants. By comparing the germination and growth rate of a group of seeds exposed to radiation being investigated with that of another group of seeds exposed to natural radiation, a reliable and effective way is provided for detection of radiation pollution.

Experiments performed by the inventor using plants grown under fluorescent lamps have revealed the existence of radiation from the electrode area of the lamp which is. different from the radiation from the lamp phosphor coating which provides the illumination. Also, the experiments showed that such electrode radiation is a form of radiation pollution in that it produces abnormal growth responses of plants exposed to fluorescent lamps as a source of illumination. Since fluorescent lamps are often used in greenhouses to'expeditc plant growth, it is desirable to eliminate such electrode radiation. The effect of electrode radiation from fluorescent lamps on animals and human beings is not known. However, since experiments have shown that unnatural radiation may produce abnormal growth responses in animals and human beings by affecting the endocrine system, it is believed to be desirable for health reasons to eliminate as far as possible all sources of radiation pollution including electrode radiation from fluorescent lamps.

Accordingly, it is an object of the present invention to provide an improved fluorescent lamp constructed to prevent emission of electrode radiation.

Another object of the invention is to provide a fluorescent lamp construction having shielding designed and located so as to prevent emission from the lamp of electrode radiation without substantial interference with the emission of the illuminating light produced by the lamp phosphors.

A further object of the invention is to provide aninexpensive radiation shield construction that can be easily applied to fluorescent lamps to prevent emission from the lamps of electrode radiation.

Further objects and advantages of the invention will become apparent as the following description proceeds.

SUMMARY It has been discovered that fluorescent lamps emit from the area of the electrodes at each end of the enclosing glass envelope radiation which penetrates the envelope and produces abnormal growth responses in plants exposed to illumination from the lamp. While the wavelength of this radiation is not known, experiments have shown that it can be shielded by use of materials, such as lead, similar to those used to shield X- rays. According to the invention, absorption shields are mounted on the fluorescent lamp so as to enclose and shield the electrode area of the lamp without masking to any great extent the light-emitting area of the tube.

For a better understanding of the invention, reference'should be made to the following detailed description taken in connection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view, partly in section, of a fluorescent lamp embodying electrode radiation shields constructed in accordance with the invention;

FIG. 2 illustrates a modified form of the shield shown in FIG. 1 arranged to prevent radiation emission from the ends of the lamp envelope;

FIG. 3 is an end view of the shield shown in FIG. 2; and

FIG. 4 illustrates a further modification of the shield construction wherein the lamp tube is provided with a circumferential groove adapted to receive inwardly bent ends of the shield.

DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS FIG. 1 of the drawing shows a fluorescent lamp provided with electrode radiation shields in accordance with the invention. The fluorescent lamp itself may be, as shown, a conventional type commonly used for artificial illumination. The lamp comprises a sealed, elongated tubular envelope made of glass having a coat ing 11 of phosphor on its inside surface and hermetically sealed at its ends to stems 12 and 13. Supported on lead-in wires extending inwardly from stems l2 and 13 are electrodes 14 and 15 which may be in the form of coiled filaments formed of tungsten wire and coated with a suitable electron-emitting material such as the usual alkaline earth oxides. Base members 16 and 17 cemented to the ends of the envelope carry contact pins 18 and 19 which are electrically connected to electrodes I4 and 15 through the lead-in wires. The contact pins 18 and 19 are adapted to be received in sockets (not shown) through which connections are made to a suitable source of alternating current power in circuit with the usual starter and ballast in a well-known manner. The envelope is filled with low-pressure mercury vapor and a rare gas such as argon. When starting voltage is applied across the electrodes, an arc discharge takes place through the filling gas emitting ultraviolet radiation which excites the phosphor coating 11 to produce visible light passing outwardly through the glass envelope as is well understood by those skilled in the art.

Experiments have been conducted by the inventor growing plants such as beans from seed using 80 watt fluorescent lamps similar to that described above as a source of artificial illumination. Seeds were planted at various distances ranging from 1 foot to 10 feet from the electrodes 14 and 15 and periodic observations made on their germination and growth rate. It was found that seeds close to the electrodes showed abnormal growth responses while those located 10 feet from the electrodes germinated and grew in a normal manner. Seeds planted at intermediate distances showed diminished abnormal growth responses the extent of which appeared to be a function of the distance from the electrodes. From these experiments it was concluded that radiation from the electrode area, as distinguished from radiation from the lamp phosphor coating, was affecting the germination and growth of the plant seeds. To verify this, the experiments were repeated with all conditions the same except that shielding material was placed between the electrode areas of the lamp and the plant seeds. The shielding material used was lead similar to that used to shield X-rays.

When shielding was used, all plant seeds germinated and grew in a normal manner and at about the same rate. In order to make a practical use of this discovery, shields are applied to fluorescent lamps in a manner to be described so as to shield the general area illuminated by the lamp from radiation apparently generated in the electrode areas of the lamp.

In the embodiment illustrated in FIG. 1, cylindrical radiation shields 20 and 21 are placed around envelope 10 adjacent the ends thereof so as to encompass the electrodes 14 and 15 as shown. The shields are formed of material having sufficient density and thickness to absorb the electrode radiation from the lamp. Shields 1/16 inch thick formed of a material having a high atomic number such as lead have been found satisfactory for use on an watt fluorescent lamp. The required radiation absorption capacity of the shields will vary with the output, operating voltage and starting characteristics of the lamp. In general, it is believed to be desirable to reduce by shielding the electrode radiation emitted by the lamp to a value not substantially exceeding natural radiation from the sun and sky so as to avoid radiation pollution in the area illuminated by the lamp. This invention is not concerned with any radiation pollution that might be caused by light emitted by the lamp phosphor coating which involves other lamp design factors such as the composition of the phosphor coating.

The shields 20 and 21 may be formed and applied to the lamp by wrapping a foil strip around the lamp having the desired thickness. Alternatively, the shields may be preformed in tubular shape and dimensioned to be slid over the ends of the tube and secured in place by any suitable method such as cementing. Another installation method is to form the shield as two half cylinders which can be installed around the electrode areas of the lamp and secured by screw or clamping fasteners. For application to large size lamps, it may be desirable to blacken the shields, for example with a carbon coating, to radiate heat effectively and avoid overheating of the lamp. Heat-radiating fins projecting from the shields may also be used for this purpose.

With shields having a cylindrical configuration such as shown in FIG. 1, most of the outward electrode radiation in the direction of arrows 22 will be intercepted and absorbed by the shield. Radiation emitted at an angle closer to an axial direction of the tube as illustrated by arrows 23 may bypass the shield and be radiated from the lamp. However, for many lamp installations where the lamps are suspended in a horizontal position near the ceiling, such escaping radiation will be directed away from the light utilization area which is usually near the floor. In order not to detract unduly from the lighting efficiency of the lamp by masking part of the lamp producing light by emission from the phosphor coating, the axial length of the shields should not be made longer than necessary to obtain the desired electrode radiation shielding.

FIG. 2 of the drawing shows a modified form of shield designed to give greater protection against emission of electrode radiation through the ends of the lamp. For this purpose a cylindrical shield 24 is provided with an end portion 25 which will intercept and absorb axially directed radiation in the direction of arrows 26. The end 25 is provided with holes 27 through which the contact pins 18 pass in spaced relation. A similar shield with holes to receive contact pins 19 may be placed on the other end of the lamp.

For applications where greater protection from electrode radiation than afforded by the shield arrangements of FIGS. 1 or 2 is desired, the modification of FIG. 4 may be used. In this arrangement a shield 27, which may be similar to the shield 24 of FIG. 2, has end portions 28 bent inwardly into a circumferential groove 29 in the envelope .10 located inwardly with respect to electrode M. Radiation in the direction of arrows 30 which would escape the shield with the configuration of FIGS. 1 and 2 is intercepted and absorbed by the end portions 28. A similar shield 31 with end portions 32 extending into an envelope groove 33 may be placed on the other end of the lamp to encompass electrode as shown. In a similar manner it will provide additional protection by intercepting radiation in the direction of arrows 34.

If desired, the electrode radiation shields may be formed integrally with the fluorescent lamp during its manufacture. F or example, sleeves formed of glass with a high lead content known as X-ray shield glass, or other suitable material, may be fused or cemented to the envelope wall around the electrode area.

The manner in which the electrode radiation is generated in a fluorescent lamp is not known. However, it may be generated by bombardment of the electrodes by electrons and ions during the half cycle of the AC. voltage when the electrode acts as an anode. For that reason the shields, which might otherwise act as radiation generators, are preferably mounted so as not to be in the stream of electrons and charged particles flowing between the lamp electrodes. This can be conveniently accomplished by mounting the shields on the outside of the lamp envelope as shown in the illustrated embodiments of the invention.

While there have been shown what are presently considered to be preferred embodiments of the invention, it will be apparent to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention.

What is claimed as new and desired to be secured by Letters Patent of the United States is:

1. In a fluorescent lamp of the type comprising a sealed, elongated tubular light-conducting envelope containing an arc-conducting gas, a light-emitting phosphor coating on the inside of the envelope and electron-emitting electrodes at each end of the envelope electrically connected to conductors extending through the ends of the envelope, shielding means for preventing emission outside the walls of the envelope of radiation generated in the electrode area of the lamp, said shielding means comprising:

a shielding member mounted on said lamp envelope outside the path of the arc discharge between the lamp electrodes and arranged to extend around the electrode area of the lamp envelope,

said shielding member being constructed of a material having a high atomic number and density, which will absorb radiation such as X-rays,

said material having sufficient thickness and axial length to absorb substantially all of the radiation emanating from the electrode area of the lamp around which it extends, which radiation would otherwise pass through the lamp envelope into the area illuminated by the lamp.

2. A fluorescent lamp as set forth in claim 1 wherein the shielding means comprises two spaced shielding members mounted on the lamp to extend around the electrodes on both ends of the lamp.

3. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed of a material comprising lead.

4. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed by wrapping foil around the electrode ends of the envelope.

5. A fluorescent lamp as set forth in claim ll wherein the shielding member is a preformed tube dimensioned to permit installation on the lamp envelope so as to encompass the electrode area.

6. A fluorescent lamp as set forth in claim 5 wherein the shielding member has an end portion designed to enclose the end of the lamp envelope, said end portion being provided with one or more holes adapted to receive said electrode conductors extending therethrough from the base of the lamp.

7. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed of a flexible material and the envelope is provided with a circumferential groove inside of the electrode area adapted to receive inwardly bent ends of the shielding member.

8. A fluorescent lamp as set forth in claim 6 wherein the shielding member is formed of a flexible material and the envelope is provided with a circumferential groove inside of the electrode area adapted to receive inwardly bent ends of the shielding member. 

1. In a fluorescent lamp of the type comprising a sealed, elongated tubular light-conducting envelope containing an arcconducting gas, a light-emitting phosphor coating on the inside of the envelope and electron-emitting electrodes at each end of the envelope electrically connected to conductors extending through the ends of the envelope, shielding means for preventing emission outside the walls of the envelope of radiation generated in the electrode area of the lamp, said shielding means comprising: a shielding member mounted on said lamp envelope outside the path of the arc discharge between the lamp electrodes and arranged to extend around the electrode area of the lamp envelope, said shielding member being constructed of a material having a high atomic number and density, which will absorb radiation such as X-rays, said material having sufficient thickness and axial length to absorb substantially all of the radiation emanating from the electrode area of the lamp around which it extends, which radiation would otherwise pass through the lamp envelope into the area illuminated by the lamp.
 2. A fluorescent lamp as set forth in claim 1 wherein the shielding means comprises two spaced shielding members mounted on the lamp to extend around the electrodes on both ends of the lamp.
 3. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed of a material comprising lead.
 4. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed by wrapping foil around the electrode ends of the envelope.
 5. A fluorescent lamp as set forth in claim 1 wherein the shielding member is a preformed tube dimensioned to permit installation on the lamp envelope so as to encompass the electrode area.
 6. A fluorescent lamp as set forth in claim 5 wherein the shielding member has an end portion designed to enclose the end of the lamp envelope, said end portion being provided with one or more holes adapted to receive said electrode conductors extending therethrough from the base of the lamp.
 7. A fluorescent lamp as set forth in claim 1 wherein the shielding member is formed of a flexible material and the envelope is provided with a circumferential groove inside of the electrode area adapted to receive inwardly bent ends of the shielding member.
 8. A fluorescent lamp as set forth in claim 6 wherein the shielding member is formed of a flexible material and the envelope is provided with a circumferential groove inside of the electrode area adapted to receive inwardly bent ends of the shielding member. 